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DOI: 10.1055/s-0044-1779685
Comparative Functional and Isokinetic Analysis between Implants with Posterior Stabilization and Rotating Hinge Total Knee Arthroplasty
Article in several languages: português | English- Abstract
- Introduction
- Materials and Methods
- Statistical analysis
- Results
- Discussion
- Conclusion
- Referências
Abstract
Objective: To compare the function and muscle strength of the limb between patients undergoing knee arthroplasties using primary implants with posterior stabilization (control group) and patients with rotating hinge implants (Hinge group).
Methods: Function assessment was performed using the Knee Society Score (KSS) and muscle strength using an isokinetic dynamometer using a speed of 60°/s.
Results: 43 patients were analyzed, who underwent 51 surgeries, with the Hinge group comprising 25 surgeries and the control group comprising 26 primary surgeries. We did not observe significant differences between the Hinge and control groups in the values of functional KSS (p = 0.54), objective KSS (p = 0.91), peak flexor torque (p = 0.25) and peak extensor torque (p = 0.08). Patients in the Hinge group who underwent primary arthroplasties had a higher peak flexor torque (0.76 Nm/kg) than those who used the implant in revision after septic failure (0.33 Nm/kg) (p < 0.05). The constrained implant was indicated in arthroplasty revision surgeries with severe ligament instability and in cases of complex primary arthroplasties with bone destruction or severe coronal deformity in the coronal plane.
Conclusion: The use of constrained implants enables joint function and muscle strength comparable to patients who underwent primary arthroplasty using conventional implants with posterior stabilization. Patients undergoing septic revision with a rotating Hinge prosthesis exhibit lower flexor muscle strength compared to those undergoing primary arthroplasty with a constrained implant.
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Introduction
Total knee arthroplasty (TKA) is a surgical procedure for replacing the knee joint with metal prostheses. It is often indicated for the treatment of severe cases of osteoarthritis, providing good or excellent results in more than 90% of patients. Normally, for primary surgeries, implants with less constriction are used, which can retain or replace the posterior cruciate ligament. In cases of complex primary surgeries or TKA revisions, implants with a greater degree of constriction are more frequently used, which may be semi-constricted or constricted (Hinge type implants).[1] Currently, severe ligament instability, massive bone destruction, ligament hyperlaxity, severe fixed deformity in the coronal plane, severe arthrofibrosis, septic arthroplasty revision, severe rheumatoid arthritis and comminuted fracture in osteoporotic bone may be an indication for the use of Hinge implants.[2] [3]
These implants were designed by Walldius,[4] in 1953, for reconstruction after tumor resection.[4] [5] However, the first generation prostheses evolved with limited clinical results, a high number of failures, limited durability and significant bone loss for revision.[6] In the second generation, despite the improvements observed in the design, the clinical results remained limited and, still, a high number of complications were observed.[7] Currently, we have the third generation of these implants, with changes in the design and use of rotating polyethylene components aiming for better distribution load and joint kinematics, as well as reducing stress at the implant-host bone interface.[8] Therefore, it is believed that modern constrained implants enable better clinical results; however, a limited number of studies evaluate the functional results of these implants, especially in the Brazilian population, and we also observed a reduced number of studies comparing the results of implants with different degrees of constriction.[9] [10]
Therefore, the objective of the present study was to compare the function and muscle strength of the limb between patients undergoing surgery using primary implants with posterior stabilization and patients with rotating hinged implants. We believe that patients with Hinge implants will have lower limb muscle strength and/or worse joint function, potentially related to the implant, but also due to the greater complexity of primary cases or because they are used in patients undergoing revision TKA, therefore, with several previous surgeries.
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Materials and Methods
From December 2009 to May 2016, 67 rotating constrained implants from the Rotation Hinge Knee (RHK) Zimmer-Biomet® system were used in 65 patients at our institution. Of these, 18 cases were complex primary arthroplasties, and 50 were total knee arthroplasty (TKA) revisions. For the present study, 24 patients who underwent 25 surgeries with Hinge-type implants were analyzed, constituting the "Hinge group". Inclusion criteria were patients undergoing TKA at the institution requiring Hinge-type constrained implants and having isokinetic evaluation. Exclusion criteria were: patients with less than one year of postoperative follow-up during the study period, non-compliance with postoperative guidelines, loss to follow-up, unfavorable outcomes with implant loss (amputation, arthrodesis), death for any reason, presence of muscle injuries, neurological injuries, extensor mechanism injuries and/or fractures in lower limbs, uncompensated systemic clinical disease, and patients residing outside the state where the study was conducted. 41 patients were excluded from the study, and the reasons were: loss to follow-up (15 patients), residence outside the state (8 patients), death (6 patients), lack of clinical conditions for isokinetic evaluation (5 patients), septic arthroplasty failure (3 patients), lack of interest in participating in the research (2 patients), and extensor mechanism failure (2 patients).
Out of the 25 surgeries in the Hinge group, 9 were primary arthroplasties, and 16 were TKA revisions. In 4 cases of primary arthroplasties, constrained implants were necessary due to bone destruction, and in 5 other cases, due to severe deformity in the coronal plane. Out of the 16 revisions, 11 were due to mechanical failures, and 5 were due to infection. The control group consisted of patients undergoing TKA with conventional primary implants with posterior stabilization, matched for age, sex, and body mass index (BMI) to the study group that used the constrained Hinge prosthesis.
Therefore, this is a retrospective case series conducted with 24 patients undergoing 25 TKAs using constrained implants with a rotating tibial platform and 19 individuals undergoing primary arthroplasties in 26 surgeries using implants with posterior stabilization. The study was previously approved by the Research Ethics Committee of the institution (CAAE: 47473315.4.0000.5273), and there was no age limit or restriction on the participants' gender.
In both groups, the following were analyzed: age, sex, follow-up time, weight, height, and BMI. The Hinge group was divided into the following subgroups: patients undergoing primary arthroplasty (primary group), patients undergoing revision after failure due to infection (septic revision group), and patients undergoing revision after aseptic failure (aseptic revision group).
The following analyses were performed between the control group and the Hinge group and between the subgroups of the Hinge group. Function evaluation was conducted through the application of the Knee Society Score (KSS), validated for the Portuguese language, consisting of an objective and a functional part.[11] The objective KSS analyzes pain, range of motion, joint stability, presence of stiffness, extension deficit, and alignment of the limb in the coronal plane. The functional part assesses the patient's mobility, the ability to go up and down stairs and the need to use aids for walking. The questionnaire was administered by two orthopedists during the postoperative follow-up consultation.
Muscle strength was analyzed using an isokinetic dynamometer (CSMI, model HUMAC NORM). To determine the maximum isokinetic voluntary strength, a concentric-concentric isokinetic test was performed for knee flexion and extension. The speed used was 60°/s and five repetitions were performed. The highest instantaneous torque found was considered the peak torque (PT) and used for the analyses. PT was standardized by body weight to enable better comparison between individuals.
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Statistical analysis
Descriptive analyses for quantitative data were conducted, presenting means, standard deviations (SD), medians, minimum and maximum values. The Shapiro-Wilk normality test and Levene's homogeneity test were employed. To compare the control and Hinge groups, the independent samples t-test was used, and when necessary, the non-parametric Mann-Whitney test. To analyze variables among the subgroups of the Hinge prosthesis, Analysis of Variance (ANOVA) and the non-parametric Kruskal-Wallis test were employed. When multiple mean comparisons were needed, the Bonferroni post hoc test and Dunn's post hoc test were used. Categorical variables were analyzed using the Chi-Square test or Fisher's Exact test when necessary. All analyses were conducted using SPSS 21 software for Windows with a significance level of α = 0.05.
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Results
The demographic data of the Hinge and control groups are described in [Table 1] and the groups were similar in terms of age, weight, height, BMI, gender distribution and length of follow-up.
Variable |
Hinge (n = 25) |
Control Group (n = 26) |
p value |
---|---|---|---|
Age (years) |
68,20 ± 9,09 |
66,40 ± 6,19 |
0,23 |
Sex |
|||
Male |
4 |
5 |
0,76 |
Female |
21 |
21 |
|
Wight (kg) |
78,42 ± 16,42 |
78,90 ± 12,95 |
0,66 |
Height (m) |
1,59 ± 0,10 |
1,63 ± 0,09 |
0,27 |
BMI (kg/m2) |
31,19 ± 6,46 |
29,51 ± 3,97 |
0,61 |
Follow-up time (months) |
32,74 ± 21,23 |
27,91 ± 18,41 |
0,37 |
There was no statistically significant difference regarding distribution by sex, age and length of follow-up between patients undergoing Hinge in primary surgery or revision surgery. The mean BMI presented different values between the groups (p = 0.02) ([Table 2]) and, after performing the Bonferroni post hoc test, a p value < 0.05 was observed only between the septic revision and aseptic revision; therefore, the septic revision subgroup (38.41 kg/m2) had a higher average than the aseptic revision subgroup (28.37 kg/m2).
Variable |
Primary (n = 9) |
Sceptic Revision (n = 5) |
Aseptic Revision (n = 11) |
p value |
---|---|---|---|---|
Age (years) |
66,73 ± 10,47 |
71,53 ± 7,02 |
67,81 ± 9,26 |
0,23 |
Sex |
||||
Male |
3 |
0 |
1 |
0,18 |
Female |
6 |
5 |
10 |
|
Wight (kg) |
75,54 ± 15,46 |
90,52 ± 22,09 |
75,27 ± 19,78 |
0,29 |
Height (m) |
1,57 ± 0,11 |
1,53 ± 0,10 |
1,62 ± 0,09 |
0,26 |
BMI (kg/m2) |
30,63 ± 6,73 |
38,41 ± 7,02 |
28,37 ± 5,43 |
0,02* |
Follow-up time (months) |
29,33 ± 25,22 |
35,51 ± 23,39 |
34,28 ± 18,33 |
0,62 |
The KSS values of the Hinge and control groups are illustrated in [Fig. 1] and did not demonstrate a significant difference between the groups. The KSS values for each type of surgery in the Hinge group are shown in [Fig. 2] and we did not observe a significant difference between the subgroups.
The peak flexor and extensor torque values corrected for weight are illustrated in [Fig. 3] and did not demonstrate significant differences between the Hinge group and the control group. [Fig. 4] shows the peak flexor and extensor torque between the different types of surgery using Hinge implants. A significant difference was observed between peak flexor torque values (p = 0.02) between the subgroups that used the Hinge implant. After performing the Bonferroni post hoc test, a difference (p < 0.05) was observed between the primary prosthesis and septic revision subgroups; therefore, the group that used the constrained prosthesis in primary arthroplasties has a higher peak flexor torque (0.76 Nm/kg) than those that used the implant in revision TKA after TKA infection (0.33 Nm/kg).
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Discussion
The present study is one of the few found in the literature evaluating results from the use of constrained prostheses in the Brazilian and Latin American populations.[12] [13] Contrary to the predicted hypothesis, the main finding was the observation that the use of constrained implants enables joint function and muscle strength comparable to that of patients who underwent primary arthroplasty using conventional implants with posterior stabilization.
In our sample, the average functional KSS was 69.80 points in the Hinge group, not statistically different from the 74.23 points observed in the control group; we also found no differences in values between the subgroups that used constrained implants. This score was higher than that observed by most studies evaluating constrained prostheses found in the literature, which showed results ranging from 36 to 69.7 points.[12] [14] [15] [16] [17] [18] [19] The two trials with values similar to ours were those by Felli et al.[16] (67,1 points) who evaluated revisions and primary arthroplasties in patients with rheumatoid arthritis and Petrou et al.[17] (69,7 points) who evaluated medium-term results of cemented primary constrained prostheses.
Similarly, when analyzing the objective KSS, no differences were observed among the three subgroups of patients who received Hinge prostheses. This demonstrates, in our sample, that the type of surgery, whether primary or revision, did not influence the final outcome of joint function. Similarly, the objective KSS score was not distinct between patients with constrained implants (87.29 points) and those with conventional primary prostheses (89.96 points). Similar data were observed by Sanguineti et al.[18], Felli et al.[16], Bohler et al.[19] and Helito et al.[12], who reported means of 94.2, 93.5, 89.0, and 89.9 points, respectively. Studies conducted by Boelch et al.[14], Arnholdt et al.[15] and Spranz et al.[20], obtained lower values, ranging from 67 to 83 points.
Muscular strength and power in the lower limbs are closely associated with physical performance and functional capacity in patients with knee pathologies. Kim et al.[21] demonstrated that the isokinetic peak torque observed preoperatively is recovered one year post-surgery, coinciding with the resumption of full activities by patients. Therefore, we believe that all patients were fully recovered at the time of the evaluation of joint function and limb muscle strength.
We conducted the assessment of muscle strength using isokinetic dynamometry, which allows for a more objective measurement than other methods. It has also been employed in various studies seeking to identify the correlation of muscle strength with different variables, such as surgical access types, anesthesia types, and rehabilitation methods. However, a limited number of studies have specifically aimed to identify the potential influence of the type of joint implant on muscle strength. In our study, we measured strength by peak torque, considering the implant type as the sole variable. We observed that the extensor peak torque was similar between patients in the Hinge group and the control group. Similarly, we did not identify differences among patients with constrained implants, whether in primary or revision surgery. Thus, we did not find that the use of Hinge-type implants influenced the extensor peak torque.
Similarly, the flexion strength measured by peak flexor torque was not different between patients with constricted implants and those with conventional postero-stabilized implants. However, when analyzing only patients in the Hinge group, we identified that patients undergoing primary surgery had higher peak flexor torque than patients undergoing septic revision. We believe that this difference may be related to the potential greater number of surgeries to control septic failure, although we did not identify distinctions regarding peak extensor torque. Pasquier et al.[22] analyzed the use of constrained implants in TKA revision surgeries and demonstrated that the use of the implant in septic revisions presented worse functional results and higher complication rates when compared to cases of aseptic failures.
Recent studies evaluating the long-term durability of the implant demonstrate excellent results, showing a 10-year survival rate for revisions of 90.2% and for primary arthroplasties in patients over 60 years of age of 94%.[8] [23] However, as seen in the literature, a relevant percentage of our patients who used Hinge presented poor results and needed to be excluded from the analysis, with three developing arthroplasty failure and two with extensor mechanism failure, totaling 7.46% of the initial sample. Although relevant, this value is lower than the average number of complications observed in arthroplasties using constrained implants, which range from 9.2 to 63%.[10] [23] [24] [25] [26] [27] [28] Most studies demonstrate an incidence of 30 to 40% of complications, the most common being: infections, injuries to the extensor mechanism, and fractures.[10] [24] [26] [29] [30]
As limitations of our research, we can mention the high number of exclusions, which occurred not only in our study but also in other similar researches that showed a follow-up loss of up to 65%.[18] [30] This can be partially explained by the social profile of the patients and the institution where the research was conducted. Many patients operated in our hospital are referred from different regions of the country, making follow-up challenging after several years of surgery. The advanced age and presence of comorbidities in this population often hinder the assessment of muscle strength and contribute to high mortality from various causes in the years following surgery.
Another significant limitation of this study is the lack of control over other variables such as surgical access, although several studies have shown that differences in functional recovery related to surgical access are observed up to 6 months. Kim et al.[21] corroborate this information by demonstrating that the peak muscle torque after one year of surgery is similar to that observed preoperatively.
Finally, we believe that the lack of sample calculation represents an important limitation of the study. However, due to the restricted indications and limited availability of constrained implants, we believe that the analysis of 25 surgeries with constrained rotating platform implants with an isokinetic dynamometer reveals significant information, although it is necessary to carry out future studies with a greater number of cases and complementary analyzes to increase the reliability of results.
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Conclusion
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The use of constrained implants enables joint function and muscle strength comparable to patients who underwent primary arthroplasty using conventional implants with posterior stabilization.
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Patients undergoing septic revision with a rotating Hinge prosthesis exhibit lower flexor muscle strength compared to those undergoing primary total knee arthroplasty (TKA) with a constrained implant.
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Work developed at the INTO – Instituto Nacional de Traumatologia e Ortopedia, Rio de Janeiro, RJ, Brazil.
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Referências
- 1 Marya SKS, Singh C. Options and limitations of implant constraint. J Orthop 2020; 23: 18-24
- 2 Gehrke T, Kendoff D, Haasper C. The role of hinges in primary total knee replacement. Bone Joint J 2014; 96-B (11, Supple A) 93-95
- 3 Bingham JS, Bukowski BR, Wyles CC, Pareek A, Berry DJ, Abdel MP. Rotating-Hinge Revision Total Knee Arthroplasty for Treatment of Severe Arthrofibrosis. J Arthroplasty 2019; 34 (7S): S271-S276
- 4 Walldius B. Arthroplasty of the knee joint employing an acrylic prosthesis. Acta Orthop Scand 1953; 23 (02) 121-131
- 5 Ruggieri P, Mavrogenis AF, Pala E, Abdel-Mota'al M, Mercuri M. Long term results of fixed-hinge megaprostheses in limb salvage for malignancy. Knee 2012; 19 (05) 543-549
- 6 Rand JA, Chao EY, Stauffer RN. Kinematic rotating-hinge total knee arthroplasty. J Bone Joint Surg Am 1987; 69 (04) 489-497
- 7 Barrack RL. Evolution of the rotating hinge for complex total knee arthroplasty. Clin Orthop Relat Res 2001; (392) 292-299
- 8 Kendoff D, Haasper C, Gehrke T, Klauser W, Sandiford N. Management of Gonarthrosis with a Rotating Hinge Prosthesis: Minimum 10-Year Follow-up. Clin Orthop Surg 2020; 12 (04) 464-469
- 9 Yoon JR, Cheong JY, Im JT, Park PS, Park JO, Shin YS. Correction: Rotating hinge knee versus constrained condylar knee in revision total knee arthroplasty: A meta-analysis. PLoS One 2019; 14 (04) e0216004
- 10 Barnoud W, Schmidt A, Swan J. et al. Condylar constrained knee prosthesis and rotating hinge prosthesis for revision total knee arthroplasty for mechanical failure have not the same indications and same results. SICOT J 2021; 7: 45
- 11 Silva ALP, Demange MK, Gobbi RG, da Silva TFC, Pécora JR, Croci AT. Translation and Validation of the Knee Society Score - KSS for Brazilian Portuguese. Acta Ortop Bras 2012; 20 (01) 25-30
- 12 Helito CP, Giglio PN, Cavalheiro CM, Gobbi RG, Demange MK, Camanho GL. Knee arthroplasty with rotating-hinge implant: an option for complex primary cases and revisions. Rev Bras Ortop 2018; 53 (02) 151-157
- 13 Angelini FJ, Helito CP, Veronesi BA, Guimarães TM, Pécora JR, Demange MK. Knee arthroplasty revision with a constrained implant using hinge and rotating tibial basis. Acta Ortop Bras 2016; 24 (01) 22-26
- 14 Boelch SP, Arnholdt J, Holzapfel BM, Jakuscheit A, Rudert M, Hoberg M. Revision knee arthroplasty with rotating hinge systems in patients with gross ligament instability. Int Orthop 2018; 42 (12) 2825-2833
- 15 Arnholdt J, Boelch SP, Dogan F, Hoberg M, Holzapfel BM, Rudert M. Revision arthroplasty with rotating hinge systems for total knee arthroplasty instability. Oper Orthop Traumatol 2020; 32 (04) 298-308
- 16 Felli L, Coviello M, Alessio-Mazzola M, Cutolo M. The Endo-Model(®) rotating hinge for rheumatoid knees : Functional results in primary and revision surgery. Orthopade 2016; 45 (05) 446-451
- 17 Petrou G, Petrou H, Tilkeridis C. et al. Medium-term results with a primary cemented rotating-hinge total knee replacement. A 7- to 15-year follow-up. J Bone Joint Surg Br 2004; 86 (06) 813-817
- 18 Sanguineti F, Mangano T, Formica M, Franchin F. Total knee arthroplasty with rotating-hinge Endo-Model prosthesis: clinical results in complex primary and revision surgery. Arch Orthop Trauma Surg 2014; 134 (11) 1601-1607
- 19 Böhler C, Kolbitsch P, Schuh R, Lass R, Kubista B, Giurea A. Midterm results of a new rotating hinge knee implant: a 5-year follow-up. BioMed Res Int 2017; 2017: 7532745
- 20 Spranz DM, Koch KA, Reiner T, Hetto P, Gotterbarm T, Merle C. Mid-term results of complex primary total knee arthroplasty using a rotating-hinge implant. Knee 2022; 34: 34-41
- 21 Kim JG, Lee SW, Ha JK, Choi HJ, Yang SJ, Lee MY. The effectiveness of minimally invasive total knee arthroplasty to preserve quadriceps strength: a randomized controlled trial. Knee 2011; 18 (06) 443-447
- 22 Pasquier G, Ehlinger M, Mainard D. The role of rotating hinge implants in revision total knee arthroplasty. EFORT Open Rev 2019; 4 (06) 269-278
- 23 Wignadasan W, Chang JS, Kayani B, Kontoghiorghe C, Haddad FS. Long-term results of revision total knee arthroplasty using a rotating hinge implant. Knee 2021; 28: 72-80
- 24 Kearns SM, Culp BM, Bohl DD, Sporer SM, Della Valle CJ, Levine BR. Rotating Hinge Implants for Complex Primary and Revision Total Knee Arthroplasty. J Arthroplasty 2018; 33 (03) 766-770
- 25 Badawy M, Fenstad AM, Furnes O. Primary constrained and hinged total knee arthroplasty: 2- and 5-year revision risk compared with unconstrained total knee arthroplasty: a report on 401 cases from the Norwegian Arthroplasty Register 1994-2017. Acta Orthop 2019; 90 (05) 467-472
- 26 Neri T, Boyer B, Papin PE. et al; and SOFCOT. Contemporary rotating hinge arthroplasty can safely be recommended in complex primary surgery. Knee Surg Sports Traumatol Arthrosc 2020; 28 (06) 1780-1788
- 27 Theil C, Schneider KN, Gosheger G. et al. Revision TKA with a distal femoral replacement is at high risk of reinfection after two-stage exchange for periprosthetic knee joint infection. [published online ahead of print, 2021 Feb 10] Knee Surg Sports Traumatol Arthrosc 2021; ••• DOI: 10.1007/s00167-021-06474-2.
- 28 Cottino U, Abdel MP, Perry KI, Mara KC, Lewallen DG, Hanssen AD. Long-Term Results After Total Knee Arthroplasty with Contemporary Rotating-Hinge Prostheses. J Bone Joint Surg Am 2017; 99 (04) 324-330
- 29 Hintze JV, Niemeläinen M, Sintonen H, Nieminen J, Eskelinen A. Good mid-term outcome of the rotating hinge knee in primary total knee arthroplasty - Results of a single center cohort of 106 knees with a median follow-up of 6.3 years. Knee 2021; 28: 273-281
- 30 von Hintze J, Niemeläinen M, Sintonen H, Nieminen J, Eskelinen A. Outcomes of the rotating hinge knee in revision total knee arthroplasty with a median follow-up of 6.2 years. BMC Musculoskelet Disord 2021; 22 (01) 336
Endereço para correspondência
Publication History
Received: 23 November 2021
Accepted: 26 June 2023
Article published online:
21 March 2024
© 2024. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution 4.0 International License, permitting copying and reproduction so long as the original work is given appropriate credit (https://creativecommons.org/licenses/by/4.0/)
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Referências
- 1 Marya SKS, Singh C. Options and limitations of implant constraint. J Orthop 2020; 23: 18-24
- 2 Gehrke T, Kendoff D, Haasper C. The role of hinges in primary total knee replacement. Bone Joint J 2014; 96-B (11, Supple A) 93-95
- 3 Bingham JS, Bukowski BR, Wyles CC, Pareek A, Berry DJ, Abdel MP. Rotating-Hinge Revision Total Knee Arthroplasty for Treatment of Severe Arthrofibrosis. J Arthroplasty 2019; 34 (7S): S271-S276
- 4 Walldius B. Arthroplasty of the knee joint employing an acrylic prosthesis. Acta Orthop Scand 1953; 23 (02) 121-131
- 5 Ruggieri P, Mavrogenis AF, Pala E, Abdel-Mota'al M, Mercuri M. Long term results of fixed-hinge megaprostheses in limb salvage for malignancy. Knee 2012; 19 (05) 543-549
- 6 Rand JA, Chao EY, Stauffer RN. Kinematic rotating-hinge total knee arthroplasty. J Bone Joint Surg Am 1987; 69 (04) 489-497
- 7 Barrack RL. Evolution of the rotating hinge for complex total knee arthroplasty. Clin Orthop Relat Res 2001; (392) 292-299
- 8 Kendoff D, Haasper C, Gehrke T, Klauser W, Sandiford N. Management of Gonarthrosis with a Rotating Hinge Prosthesis: Minimum 10-Year Follow-up. Clin Orthop Surg 2020; 12 (04) 464-469
- 9 Yoon JR, Cheong JY, Im JT, Park PS, Park JO, Shin YS. Correction: Rotating hinge knee versus constrained condylar knee in revision total knee arthroplasty: A meta-analysis. PLoS One 2019; 14 (04) e0216004
- 10 Barnoud W, Schmidt A, Swan J. et al. Condylar constrained knee prosthesis and rotating hinge prosthesis for revision total knee arthroplasty for mechanical failure have not the same indications and same results. SICOT J 2021; 7: 45
- 11 Silva ALP, Demange MK, Gobbi RG, da Silva TFC, Pécora JR, Croci AT. Translation and Validation of the Knee Society Score - KSS for Brazilian Portuguese. Acta Ortop Bras 2012; 20 (01) 25-30
- 12 Helito CP, Giglio PN, Cavalheiro CM, Gobbi RG, Demange MK, Camanho GL. Knee arthroplasty with rotating-hinge implant: an option for complex primary cases and revisions. Rev Bras Ortop 2018; 53 (02) 151-157
- 13 Angelini FJ, Helito CP, Veronesi BA, Guimarães TM, Pécora JR, Demange MK. Knee arthroplasty revision with a constrained implant using hinge and rotating tibial basis. Acta Ortop Bras 2016; 24 (01) 22-26
- 14 Boelch SP, Arnholdt J, Holzapfel BM, Jakuscheit A, Rudert M, Hoberg M. Revision knee arthroplasty with rotating hinge systems in patients with gross ligament instability. Int Orthop 2018; 42 (12) 2825-2833
- 15 Arnholdt J, Boelch SP, Dogan F, Hoberg M, Holzapfel BM, Rudert M. Revision arthroplasty with rotating hinge systems for total knee arthroplasty instability. Oper Orthop Traumatol 2020; 32 (04) 298-308
- 16 Felli L, Coviello M, Alessio-Mazzola M, Cutolo M. The Endo-Model(®) rotating hinge for rheumatoid knees : Functional results in primary and revision surgery. Orthopade 2016; 45 (05) 446-451
- 17 Petrou G, Petrou H, Tilkeridis C. et al. Medium-term results with a primary cemented rotating-hinge total knee replacement. A 7- to 15-year follow-up. J Bone Joint Surg Br 2004; 86 (06) 813-817
- 18 Sanguineti F, Mangano T, Formica M, Franchin F. Total knee arthroplasty with rotating-hinge Endo-Model prosthesis: clinical results in complex primary and revision surgery. Arch Orthop Trauma Surg 2014; 134 (11) 1601-1607
- 19 Böhler C, Kolbitsch P, Schuh R, Lass R, Kubista B, Giurea A. Midterm results of a new rotating hinge knee implant: a 5-year follow-up. BioMed Res Int 2017; 2017: 7532745
- 20 Spranz DM, Koch KA, Reiner T, Hetto P, Gotterbarm T, Merle C. Mid-term results of complex primary total knee arthroplasty using a rotating-hinge implant. Knee 2022; 34: 34-41
- 21 Kim JG, Lee SW, Ha JK, Choi HJ, Yang SJ, Lee MY. The effectiveness of minimally invasive total knee arthroplasty to preserve quadriceps strength: a randomized controlled trial. Knee 2011; 18 (06) 443-447
- 22 Pasquier G, Ehlinger M, Mainard D. The role of rotating hinge implants in revision total knee arthroplasty. EFORT Open Rev 2019; 4 (06) 269-278
- 23 Wignadasan W, Chang JS, Kayani B, Kontoghiorghe C, Haddad FS. Long-term results of revision total knee arthroplasty using a rotating hinge implant. Knee 2021; 28: 72-80
- 24 Kearns SM, Culp BM, Bohl DD, Sporer SM, Della Valle CJ, Levine BR. Rotating Hinge Implants for Complex Primary and Revision Total Knee Arthroplasty. J Arthroplasty 2018; 33 (03) 766-770
- 25 Badawy M, Fenstad AM, Furnes O. Primary constrained and hinged total knee arthroplasty: 2- and 5-year revision risk compared with unconstrained total knee arthroplasty: a report on 401 cases from the Norwegian Arthroplasty Register 1994-2017. Acta Orthop 2019; 90 (05) 467-472
- 26 Neri T, Boyer B, Papin PE. et al; and SOFCOT. Contemporary rotating hinge arthroplasty can safely be recommended in complex primary surgery. Knee Surg Sports Traumatol Arthrosc 2020; 28 (06) 1780-1788
- 27 Theil C, Schneider KN, Gosheger G. et al. Revision TKA with a distal femoral replacement is at high risk of reinfection after two-stage exchange for periprosthetic knee joint infection. [published online ahead of print, 2021 Feb 10] Knee Surg Sports Traumatol Arthrosc 2021; ••• DOI: 10.1007/s00167-021-06474-2.
- 28 Cottino U, Abdel MP, Perry KI, Mara KC, Lewallen DG, Hanssen AD. Long-Term Results After Total Knee Arthroplasty with Contemporary Rotating-Hinge Prostheses. J Bone Joint Surg Am 2017; 99 (04) 324-330
- 29 Hintze JV, Niemeläinen M, Sintonen H, Nieminen J, Eskelinen A. Good mid-term outcome of the rotating hinge knee in primary total knee arthroplasty - Results of a single center cohort of 106 knees with a median follow-up of 6.3 years. Knee 2021; 28: 273-281
- 30 von Hintze J, Niemeläinen M, Sintonen H, Nieminen J, Eskelinen A. Outcomes of the rotating hinge knee in revision total knee arthroplasty with a median follow-up of 6.2 years. BMC Musculoskelet Disord 2021; 22 (01) 336